The ubiquitin-proteasome system (UPS) controls protein abundance and is essential for many aspects of neuronal function. In ataxia (ax J ) mice, profound neurological and synaptic defects result from a loss-of-function mutation in the proteasome-associated deubiquitinating enzyme Usp14, which is required for recycling ubiquitin from proteasomal substrates. Here, we show that transgenic complementation of ax J mice with neuronally expressed ubiquitin prevents early postnatal lethality, restores muscle mass, and corrects developmental and functional deficits resultingfromthelossofUsp14,demonstratingthatubiquitindeficiencyisamajorcauseoftheneurologicaldefectsobservedinthe ax J mice.We also show that proteasome components are normally induced during the first 2 weeks of postnatal development, which coincides with dramatic alterations in polyubiquitin chain formation. These data demonstrate a critical role for ubiquitin homeostasis in synaptic development and function, and show that ubiquitin deficiency may contribute to diseases characterized by synaptic dysfunction.
Alexander Disease (AxD) is a ‘gliopathy’ caused by toxic, dominant gain-of-function mutations in the glial fibrillary acidic protein (GFAP) gene. Two distinct types of AxD exist. Type I AxD affected individuals develop cerebral symptoms by four years of age and suffer from macrocephaly, seizures, and physical and mental delays. As detection and diagnosis have improved, approximately half of all AxD patients diagnosed have onset >4 years and brainstem/spinal cord involvement. Type II AxD patients experience ataxia, palatal myoclonus, dysphagia and dysphonia. No study has examined a mechanistic link between the GFAP mutations and caudal symptoms present in type II AxD patients. We demonstrate that two key astrocytic functions, the ability to regulate extracellular glutamate and to take up K+ via K+ channels, are compromised in hindbrain regions and spinal cord in AxD mice. Spinal cord astrocytes in AxD transgenic mice are depolarized relative to WT littermates, and have a threefold reduction in Ba2+-sensitive Kir4.1 mediated currents and six-fold reduction in glutamate uptake currents. The loss of these two functions is due to significant decreases in Kir4.1 (>70%) and GLT-1 (>60%) protein expression. mRNA expression for KCNJ10 and SLC1A2, the genes that code for Kir4.1 and GLT-1, are significantly reduced by postnatal day 7. Protein and mRNA reductions for Kir4.1 and GLT-1 are exacerbated in AxD models that demonstrate earlier accumulation of GFAP and increased Rosenthal fiber formation. These findings provide a mechanistic link between the GFAP mutations/overexpression and the symptoms in those affected with type II AxD.
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